The equations of motion of the soliton transported bio-energy in the protein,were heretofore already obtained by a combination of quantum-mechanical and classical methods,but here have been derived based completely on...The equations of motion of the soliton transported bio-energy in the protein,were heretofore already obtained by a combination of quantum-mechanical and classical methods,but here have been derived based completely on quantum mechanics.And we point out the shortcoming of no self-consistency of the Davydov theory.Some interesting results have also been got.展开更多
The thermal stability of the soliton excited in protein in the biological temperature range of 300-310K have been studied by means of the quantum theory in our theory.The lifetimes of the soliton obtained are in the r...The thermal stability of the soliton excited in protein in the biological temperature range of 300-310K have been studied by means of the quantum theory in our theory.The lifetimes of the soliton obtained are in the range of 10^(-9)-10^(-8) s from 300-310K.This result shows that the soliton is very stable in the biologic temperature range and quite useful in biological processes.展开更多
文摘The equations of motion of the soliton transported bio-energy in the protein,were heretofore already obtained by a combination of quantum-mechanical and classical methods,but here have been derived based completely on quantum mechanics.And we point out the shortcoming of no self-consistency of the Davydov theory.Some interesting results have also been got.
文摘The thermal stability of the soliton excited in protein in the biological temperature range of 300-310K have been studied by means of the quantum theory in our theory.The lifetimes of the soliton obtained are in the range of 10^(-9)-10^(-8) s from 300-310K.This result shows that the soliton is very stable in the biologic temperature range and quite useful in biological processes.